Vacuum shroud for hand-held drill

ABSTRACT

An assembly for a hand-held drill is disclosed. The assembly includes a drill guide and a vacuum shroud. The drill guide includes a mount, a telescoping guard, and a guide foot. The mount is configured to couple to a non-rotating portion of the hand-held drill. The telescoping guard extends from the mount. The guide foot is coupled to the telescoping guard opposite the mount such that the drill guide enshrouds a drill bit of the hand-held drill when the telescoping guard is in an extended position. The vacuum shroud is removably fastenable to the drill guide. The vacuum shroud includes an outer wall and a vacuum hose connector. The outer wall forms an elongate vacuum cavity between an inlet proximate to the guide foot and an outlet distal from the guide foot. A vacuum hose connector is positioned at the outlet distal from the guide foot.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 17/070,856, filed Oct. 14, 2020, which is a continuation-in-part of U.S. patent application Ser. No. 16/819,868, filed Mar. 16, 2020, the entirety of both of which are hereby incorporated herein by reference for all purposes.

FIELD

The present disclosure relates generally to the field of hand-held tools, and more specifically to a vacuum shroud for a hand-held drill.

BACKGROUND

A drill guide may be used to align a drill bit of a hand-held drill with a surface of a material to be drilled. The drill guide enables smooth and controlled operation of the hand-held drill during manual drilling operations. In particular, the drill guide prevents the drill bit from slipping when initially breaching the surface of the material to start drilling a hole. Further, the drill guide maintains the drill bit continually in alignment with the surface as the drill bit is driven into the material to form a straight hole.

SUMMARY

An assembly for a hand-held drill is disclosed. The assembly includes a drill guide and a vacuum shroud. The drill guide includes a mount, a telescoping guard, and a guide foot. The mount is configured to couple to a non-rotating portion of the hand-held drill. The telescoping guard extends from the mount. The telescoping guard is configured to telescope into a retracted position from an extended position. The guide foot is coupled to the telescoping guard opposite the mount such that the drill guide enshrouds a drill bit of the hand-held drill when the telescoping guard is in the extended position. The drill bit passes through an opening in the guide foot as the telescoping guard telescopes into the retracted position from the extended position. The vacuum shroud is removably fastenable to the drill guide. The vacuum shroud includes an outer wall and a vacuum hose connector. The outer wall forms an elongate vacuum cavity between an inlet proximate to the guide foot and an outlet distal from the guide foot. A vacuum hose connector is positioned at the outlet distal from the guide foot.

The features, functions, and advantages that have been discussed can be achieved independently in various embodiments or may be combined in yet other embodiments further details of which can be seen with reference to the following description and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an exemplary hand-held drill.

FIG. 2 shows an exemplary drill guide coupled to the hand-held drill of FIG. 1 when the drill guide is in an extended position.

FIG. 3 shows the exemplary drill guide of FIG. 2 in a retracted position.

FIG. 4 shows an exemplary drill guide including a drill stop, wherein the drill guide is in an extended position.

FIG. 5 shows the exemplary drill guide of FIG. 4 in a retracted position.

FIG. 6 shows an exploded view of the exemplary drill guide of FIG. 2 .

FIG. 7 shows a cross-section of an exemplary rear-action drill guide.

FIG. 8 shows a cross-section of the exemplary rear-action drill guide of FIG. 7 in an extended position and coupled to a hand-held drill.

FIG. 9 shows a cross-section of the exemplary rear-action drill guide of FIG. 7 in a retracted position and coupled to a hand-held drill.

FIG. 10 shows a cross-section of the exemplary rear-action drill guide of FIG. 7 coupled to a hand-held drill and with a spindle lock engaged to lock a spindle of the hand-held drill.

FIG. 11 shows a cross-section of an exemplary forward-action drill guide in an extended position and coupled to a hand-held drill.

FIG. 12 shows a cross-section of the exemplary forward-action drill guide of FIG. 11 in a retracted position and coupled to a hand-held drill.

FIG. 13 shows an exemplary chucked hand-held drill.

FIG. 14 shows an exemplary drill guide coupled to the chucked hand-held drill of FIG. 13 when the drill guide is in an extended position.

FIG. 15 shows the exemplary drill guide of FIG. 14 in a retracted position.

FIG. 16 shows an exploded view of the exemplary drill guide of FIG. 14 .

FIGS. 17-19 show a twist-to-lock mechanism of the exemplary drill guide of FIG. 14 .

FIG. 20 shows aspects of an exemplary drill guide including a mount and a coupler integral with the mount and forming a chuck access window.

FIG. 21 shows the exemplary drill guide of FIG. 14 in an extended position and coupled to a chucked hand-held drill such that a chuck access window is aligned with a chuck of the chucked hand-held drill.

FIG. 22 shows the exemplary drill guide of FIG. 14 in a retracted position and coupled to a chucked hand-held drill such that a chuck access window is aligned with a chuck of the chucked hand-held drill.

FIG. 23 shows an exterior view of an exemplary vacuum shroud. FIG. 24 shows an interior view of the exemplary vacuum shroud of

FIG. 23 .

FIG. 25 shows a partial cross-section view of the exemplary vacuum shroud of FIG. 23 .

FIG. 26 shows an exemplary drill guide coupled to a hand-held drill.

FIG. 27 shows the exemplary vacuum shroud of FIG. 23 fastened to the exemplary drill guide of FIG. 26 .

FIGS. 28-29 show another embodiment of an exemplary vacuum shroud including inner and outer walls that enclose an elongate vacuum cavity.

DETAILED DESCRIPTION

A drill guide may be used to align a drill bit of a hand-held drill with a surface of a material to be drilled. For example, one state of the art type of drill guide is a separate component that requires a human operator to manually hold the drill guide in place against a surface, and manually aim and insert the drill bit into the drill guide. Since the human operator of the hand-held drill is required to hold this type of drill guide in place in proximity to the drill bit during manual drilling operations, the operator's hand is at risk of contacting the drill bit, such as if the drill and/or the operator's hand slips, or if the drill bit fractures or comes loose during a drilling operation. Moreover, the operator's hand is also at risk of being struck by debris from the manual drilling operation.

The present description is directed to a drill guide for a drill bit of a hand-held drill that couples to a non-rotating portion of the hand-held drill and provides protection for an operator's hands during manual drilling operations. In one example, the drill guide includes a telescoping guard that enshrouds the drill bit during manual drilling operations, such that the operator's hands are not exposed to the drill bit and/or drilling debris. Also, the telescoping guard is configured such that one of the operator's hands can safely hold the telescoping guard to provide additional support of the hand-held drill and drill guide during manual drilling operations.

FIG. 1 shows an exemplary hand-held drill 100. The hand-held drill 100 includes a body 102, a spindle 104, a quick release mechanism 106, and a drill bit 108. The body 102 forms a non-rotating portion of the hand-held drill 100. The spindle 104, the quick release mechanism 106, and the drill bit 108 collectively form a rotating portion of the hand-held drill 100. The spindle 104 forms an external rotating axis that extends from the body 102. The spindle 104 is coupled to the quick release mechanism 106. The quick release mechanism 106 is configured to switch between a retention state and a release state. In the retention state, the quick release mechanism 106 is configured to retain the drill bit 108 in a fixed position relative to the spindle 104. In the release state, the quick release mechanism 106 is configured to allow the drill bit 108 to be inserted into and removed from the quick release mechanism 106. The quick release mechanism 106 may be configured to selectively retain any suitable type of drill bit. Moreover, the quick release mechanism 106 may quickly transition (e.g., responsive to manual manipulation) between the release state and the retention state to change drill bits.

The body 102 includes an upper motor housing 110, a collar 112, a handle 114, a trigger 116, and a power interface 118. The upper motor housing 110 contains a motor (not shown) configured to rotate the spindle 104, the quick release mechanism 106, and the drill bit 108 responsive to actuation of the trigger 116. The collar 112 is affixed to the upper motor housing 110 such that the collar 112 is part of the non-moving portion of the body 102. The collar 112 contains a drive gear (not shown) configured to translate motor torque from the motor to rotate the spindle 104, quick release mechanism 106, and drill bit 108. The handle 114 is configured to be grasped by a hand of an operator of the hand-held drill 100. The trigger 116 is actuatable to activate the drill motor and cause rotation of the drill bit 108. The hand-held drill 100 may be configured to rotate the drill bit 108 clockwise or counterclockwise based on a state of a rotation selector (not shown). The power interface 118 is configured to connect the hand-held drill 100 to a power source that is configured to provide power to the drill's motor. In the illustrated embodiment, the hand-held drill 100 is a pneumatic drill, and the power interface 118 is configured to connect to a pneumatic power source, such as an air compressor. In other embodiments, the hand-held drill may be powered via a different power source (e.g., AC power or a DC battery). Drill 100 is non limiting, and the drill guides disclosed herein may be adapted to work with virtually any hand-held drill.

FIGS. 2 and 3 show an exemplary drill guide 200 configured to couple to the hand-held drill 100 of FIG. 1 . The drill guide 200 includes a mount 202, a telescoping guard 204, and a guide foot 206. The telescoping guard 204 extends from the mount 202. The guide foot 206 is coupled to the telescoping guard 204 opposite the mount 202.

The mount 202 is configured to couple to a non-rotating portion of the hand-held drill 100 and coaxially align the telescoping guard 204 and the guide foot 206 with the drill bit 108. In the illustrated embodiment, the mount 202 is configured to clamp to the non-rotating collar 112 shown in FIG. 1 . In other embodiments, the mount may be configured to couple to a different non-rotating component of the hand-held drill and/or couple in a non-clamping fashion.

When the telescoping guard 204 is in the extended position, the drill guide 200 fully enshrouds the drill bit 108. In other words, the telescoping guard 204 forms a physical barrier between the drill bit 108 and a human operator's hands so that the human operator's hands are protected from the drill bit 108. In the illustrated example, the telescoping guard 204 cylindrically enshrouds the drill bit 108, although differently-shaped telescoping guards may be used. A working end of the drill bit 108 may be substantially flush with, or retracted into, the telescoping guard 204 relative to an exterior edge 208 of the guide foot 206 when the telescoping guard 204 is in the extended position. As such, the human operator's hands are protected from even the working tip of the drill bit 108. Nonetheless, the human operator may use the guide foot to precisely aim the drill bit while the drill bit remains enshrouded in the telescoping guard 204.

The telescoping guard 204 is configured to telescope between a retracted position (shown in FIG. 3 ) and an extended position (shown in FIG. 2 ). For example, during use, the telescoping guard 204 telescopes from the extended position into the retracted position, thus allowing the drill bit 108 to penetrate into a material being drilled (not shown). In particular, the telescoping guard 204 includes an interior guard 210 coupled to the mount 202 and an exterior guard 212 coupled to the guide foot 206. The exterior guard 212 is telescopically coupled around the interior guard 210. As illustrated, the interior guard 210 and the exterior guard 212 are cylindrical tubes having different diameters that allow telescoping action. In FIG. 2 , the exterior guard 212 has an inner diameter that is greater than an outer diameter of the interior guard 210 such that the interior guard 210 telescopes into the exterior guard 212. The telescoping guard 204 is fully retracted when the exterior guard 212 abuts the mount 202. The drill bit 108 passes through both the interior guard 210 and the exterior guard 212, and then the guide foot 206, as the telescoping guard 204 telescopes into the retracted position from the extended position, such that the drill bit 108 continues to be enshrouded collectively by the drill guide 200 and the material being drilled as the drill bit 108 drills into the material. In this way, the drill bit 108 is not exposed to an operator's hand during manual drilling operations.

The guide foot 206 is configured to align the drill bit 108 normal to a surface of a material to be drilled by the hand-held drill 100. Such surface-normal alignment is achieved by the drill bit 108 being coaxially aligned with the guide foot 206 via the coupling of the mount 202 to the non-rotating portion of the hand-held drill 100. In other embodiments, the guide foot may be angled to align the drill bit at a desired, non-normal angle (e.g., 45 degrees).

The configuration shown in FIGS. 2 and 3 may be referred to as “rear action,” because the rear/proximal end (left side) of the telescoping guard 204 is interior the front/distal end (right side) of the telescoping guard when the drill guide telescopes.

FIGS. 4-5 show an alternative embodiment of the drill guide 200 that includes a drill stop 400. The drill stop 400 dictates a telescopic range of motion of the telescoping guard 204 that correspondingly dictates a drill depth of the drill bit 108. The drill stop 400 is configured to be translated longitudinally along the interior guard 210 when the drill guide is in the extended position (shown in FIG. 4 ). Further, the drill stop 400 is configured to be selectively clamped or otherwise affixed to the interior guard 210 at a desired longitudinal position, thus setting the depth of the drill bit 108. The drill stop 400 may be configured to selectively clamp or otherwise affix to the interior guard 210 using any suitable mechanism. The telescoping guard 204 is configured to telescope into the retracted position (shown in FIG. 5 ) from the extended position (shown in FIG. 4 ). In particular, the interior guard 210 telescopes into the exterior guard 212 until the exterior guard 212 abuts the drill stop 400, at which point the drill bit 108 extends beyond the exterior edge 208 of the guide foot 206 by the desired depth. The drill stop 400 may be used to set the drill depth of the drill bit 108 such that the drill bit 108 does not drill deeper than a desired drill depth.

FIG. 6 shows an exploded view of the drill guide 200. The mount 202 includes a clamp bolt 600 configured to screw into a threaded aperture 602 to selectively reduce an interior diameter of the mount 202, to clamp to a non-rotating portion of a hand-held drill, such as the non-rotating collar 112 of the hand-held drill 100 shown in FIG. 1 . The mount may include any suitable coupling mechanism to couple to a non-rotating portion of a hand-held drill. The mount 202 includes a neck 604 having an interior diameter sized to accommodate a drill bit, such as the drill bit 108 of the hand-held drill 100 shown in FIG. 1 . The neck 604 has an exterior diameter that is matched to an interior diameter of the interior guard 210 such that the interior guard 210 slides over the neck 604 to couple the mount 202 to the telescoping guard 204.

The mount may have an interior diameter sized to accommodate any suitable drill geometry. In some embodiments, the mount may be one of a plurality of differently-configured mounts that can be switched out of the drill guide to match different drill geometries (e.g., having different bore diameters). In some embodiments, a drill may be preconfigured to receive a complementary mount; while in some embodiments, the mount may be configured to couple to a drill that was not originally designed with a telescoping guard in mind.

Illustrated mount 202 includes a pair of spindle lock assemblies 606 (e.g., 606A and 606B). Each spindle lock assembly 606 includes a lock button 608 (e.g., 608A and 608B), a bias spring 610 (e.g., 610A and 610B), a lock retainer 612 (e.g., 612A and 612B), and a pair of lock screws 614 (e.g., 614A and 614B). The lock button 608 and the bias spring 610 are inserted into an opening 616 in the mount 202. The opening 616 is configured to align with a spindle of a hand-held drill when the drill guide is coupled to the hand-held drill. The lock button 608 and the bias spring 610 are retained in the opening 616 by the lock retainer 612, which is coupled to the mount 202 via the pair of lock screws 614. The bias spring 610 is configured to push the lock button 608 outward such that the lock button 608 does not engage the spindle. Further, the lock button 608 may be pushed inward with enough force to overcome the spring force of the bias spring 610 to engage the spindle and prevent the spindle and correspondingly the drill bit from rotating. The pair of lock buttons 608 may be used in conjunction to lock the spindle in place to allow a user to manually rotate the assembly of the integrated drill guide and the hand-held drill.

A rod wiper 618, an internal bushing 620, and an internal retaining ring 622 are configured to be coupled inside a rear end 624 of the exterior guard 212. The rod wiper 618 has an interior diameter that is greater than the exterior diameter of the interior guard 210. The rod wiper 618 has an exterior diameter that is less than the interior diameter of the exterior guard 212. The rod wiper 618 is configured to keep the telescoping guard 204 clean and free from foreign matter by preventing contaminants from reaching an interior portion of the telescoping guard 204. The rod wiper 618 may include any suitable compliant material that can create a seal between the interior guard 210 and the exterior guard 212, such as silicone, rubber, or another elastomer polymer.

The internal bushing 620 has an interior diameter that is greater than the exterior diameter of the interior guard 210. The internal bushing 620 has an exterior diameter that is less than the interior diameter of the exterior guard 212. The internal bushing 620 is configured to reduce friction between the interior guard 210 and the exterior guard 212 during telescoping operation of the telescoping guard 204. The internal bushing 620 may be any suitable friction reducing material, such as cast or machined metals, stabilized polymers (i.e., plastics), fiber-wound composites, and combinations of different types of materials. In other embodiments, bearings may be used to reduce friction between the interior guard and the exterior guard.

The internal retaining ring 622 has an interior diameter that is greater than the exterior diameter of the interior guard 210. The internal retaining ring 622 is deformable to fit within a notch (not shown) in an interior surface of the exterior guard 212 proximate to the rear end 624. When inserted in the notch, the internal retaining ring 622 retains the rod wiper 618 and the internal bushing 620 within the rear end 624 of the exterior guard 212. Moreover, the retainer ring 622 retains the interior guard 210 within the exterior guard 212, such that the guards cannot telescope apart when the telescoping guard 204 is in the extended position.

The interior guard 210 has an interior diameter that is greater than the exterior diameter of the neck 604 of the mount 202, such that the neck 604 is inserted into the interior guard 210. The neck 604 includes threads 626 that are matched to complementary threads (not shown) within the interior guard 210, such that the interior guard 210 can be screwed onto the neck 604 to couple the interior guard 210 to the mount 202. In some examples, the threads 626 are “left-handed”, such that the interior guard 210 remains tightened on the neck 604 during manual drilling operations, even if the drill bit exerts a rotational torque on the drill guide 200. The interior guard may couple to the mount in any suitable manner.

The interior guard 210 includes a retention flange 628 having a greater exterior diameter than the exterior diameter of the remainder of the interior guard 210. The exterior diameter of the retention flange 628 is greater than the interior diameter of the retaining ring 622, such that when the rod wiper 618, the internal bushing 620, and the retaining ring 622 are installed within the exterior guard 212, the retaining ring 622 abuts against the retention flange 628. In this way, the exterior guard 212 is retained on the interior guard 210 when the telescoping guard 204 is fully extended.

A coil spring 630 is positioned intermediate the interior guard 210 and the guide foot 206. The coil spring 630 is configured to bias the telescoping guard 204 toward the extended position, such that the drill bit may be enshrouded absent a retraction force that overcomes the bias of the coil spring 630.

The guide foot 206 has an exterior diameter that is less than an interior diameter of the exterior guard 212, such that the guide foot 206 can be inserted into the exterior guard 212. The guide foot 206 includes threads 632 that are matched to complementary threads (not shown) that are positioned within a front end 625 of the exterior guard 212, such that the guide foot 206 can be screwed onto the exterior guard 212 to couple the exterior guard 212 to the guide foot 206. In some examples, the threads 632 are “left-handed”, such that the exterior guard 212 remains tightened on the guide foot 206 during manual drilling operations, even if the drill bit exerts a rotational torque on the drill guide 200. The exterior guard may couple to the guide foot in any suitable manner.

The guide foot 206 includes a plurality of cut-outs 634 that are each configured to allow drilling debris to be expelled from the guide foot 206 in a controlled manner during manual drilling operations. In this way, a likelihood that the drill bit is inhibited by drilling debris is reduced.

The guide foot 206 includes a bushing 636 having an exterior diameter less than an interior diameter of the guide foot 206. The bushing 636 includes threads 638 that are matched to complementary threads (not shown) that are positioned within the guide foot 206, such that the bushing 636 can be screwed into the guide foot 206. In some examples, the threads 638 are “left-handed”, such that the bushing 636 remains tightened within the guide foot 206 during manual drilling operations, even if the drill bit exerts a rotational torque on the drill guide 200. The bushing may couple to the guide foot in any suitable manner. The bushing 636 has an interior diameter matched to a diameter of the drill bit (i.e., the bushing 636 is large enough to allow the drill bit to freely rotate, but small enough to severely limit or prevent lateral deflection of the drill bit). The bushing 636 is configured such that the drill bit passes through the bushing 636 as the telescoping guard 204 telescopes into the retracted position from the extended position. The matched interior diameter of the bushing 636 provides lateral stability to help maintain alignment of the drill bit relative to the surface of the material being drilled during manual drilling operations. The bushing 636 includes a chip breaker 640 that is configured to break drilling debris into pieces suitably small enough to be expelled through the plurality of cut-outs 634 in a controlled manner.

In some embodiments, the bushing 636 may be one of a plurality of different bushings that are each configured to be interchangeably coupled to the guide foot 206. In some examples, different bushings may have different interior diameters to accommodate differently-sized drill bits. In some examples, different bushing may have different types of chip breakers that are configured to break up different types of material. Any suitable type of bushing may be interchangeably coupled into the guide foot 206.

FIGS. 7-10 show cross-section views of the drill guide 200. In FIG. 7 , the drill guide 200 is shown not coupled to a hand-held drill, and the telescoping guard 204 is biased to the extended position by the spring 630. Further, the spindle lock assemblies 606 are biased radially outward. In particular, the bias springs 610 push the lock buttons 608 radially outward, such that the lock buttons 608 do not protrude into the interior of the mount 202.

In FIG. 8 , the drill guide 200 is shown coupled to the hand-held drill 100, with the telescoping guard 204 in the extended position. When the drill guide 200 is coupled to the hand-held drill 100, the mount 202, the telescoping guard 204, and the guide foot 206 including the bushing 636 are coaxially aligned with the drill bit 108 along a longitudinal axis 800. However, this is not strictly required, as differently-configured mounts and telescoping guards could be eccentrically aligned. When the telescoping guard 204 is in the extended position, the drill guide 200 fully enshrouds the drill bit 108, and the working end of the drill bit 108 is substantially flush with the exterior edge 208 of the guide foot 206. Additionally, when the drill guide 200 is coupled to the hand-held drill 100, the collar 112 of the hand-held drill 100 abuts the mount 202, such that the lock buttons 608 of the spindle lock assemblies 606 align with the spindle 104 of the hand-held drill 100.

In FIG. 9 , the drill guide 200 is again shown coupled to the hand-held drill 100, but with the telescoping guard 204 in the retracted position. The telescoping guard 204 telescopes with rear-action along the longitudinal axis 800 from the extended position toward the retracted position, as shown by the horizontal directional arrows 900A, 900B in FIG. 9 . When the telescoping guard 204 telescopes from the extended position toward the retracted position, the interior guard 210 translates into the exterior guard 212, and the interior guard 210 compresses the spring 630. Further, when the telescoping guard 204 telescopes from the extended position to the retracted position, the drill bit 108 passes through the guide foot 206 including the bushing 636, such that the drill bit 108 extends beyond the exterior edge 208 of the guide foot 206.

In FIG. 10 , the drill guide 200 is again shown coupled to the hand-held drill 100, with the telescoping guard 204 in the retracted position, and with the spindle lock assemblies 606 engaged with the spindle 104 of the hand-held drill 100. In particular, the lock buttons 608 are pushed radially inward, as shown by the vertical directional arrows 1000A, 1000B, such that the lock buttons 608 compress the bias springs 610 and engage the spindle 104 on opposing sides to lock the spindle 104 in place to allow a user to manually rotate the assembly of the drill guide and the hand-held drill.

FIGS. 11 and 12 show cross-section views of an exemplary forward-action drill guide 1100 shown coupled to the hand-held drill 100 of FIG. 1 . The drill guide 1100 includes a mount 1102 configured to couple to the collar 112 of the hand-held drill 100. A telescoping guard 1104 extends from the mount 1102. A guide foot 1106 is coupled to the telescoping guard 1104 opposite the mount 1102.

Unlike the telescoping guard 204 of the drill guide 200 as shown in FIGS. 2-9 , the telescoping guard 1104 is configured to telescope between a retracted position and an extended position via forward action. That is, the telescoping guard 1104 includes an exterior guard 1110 coupled to the mount 1102 and an interior guard 1110 coupled to the guide foot 1106. The exterior guard 1108 has an inner diameter that is greater than an outer diameter of the interior guard 1110 such that the interior guard 1110 telescopes into the exterior guard 1108. A coil spring 1114 is positioned intermediate the mount 1102 and the interior guard 1110 within the exterior guard 1108. The coil spring 1114 is configured to bias the telescoping guard 1104 toward the extended position by pushing the interior guard 1110 away from the mount 1102.

The guide foot 1106 includes a bushing 1116 having an interior diameter matched to a diameter of the drill bit. The bushing 1116 is configured such that the drill bit passes through the bushing 1116 as the telescoping guard 1104 telescopes into the retracted position from the extended position. The matched interior diameter of the bushing 1116 provides lateral stability to help maintain alignment of the drill bit relative to a surface of a material being drilled during manual drilling operations.

In FIG. 11 , the telescoping guard 1104 is in the extended position such that the mount 202, the telescoping guard 1104, and the guide foot 1106 including the bushing 1116 fully enshroud the drill bit 108. In this state, the drill bit 108 does not extend beyond an exterior edge 1120 of the guide foot. Further, the mount 202, the telescoping guard 1104, and the guide foot 1106 including the bushing 1116 are coaxially aligned with the drill bit 108 along a longitudinal axis 1118 of the drill bit.

In FIG. 12 , the telescoping guard 1104 is shown in the retracted position such that the interior guard 1110 telescopes rearward into the exterior guard 1108 along the longitudinal axis 1118 and compresses the coil spring 1114, as shown by the horizontal directional arrows 1200A, 1200B in FIG. 12 . When the telescoping guard 1104 telescopes from the extended position toward the retracted position, the drill bit 108 passes through the guide foot 1106 including the bushing 1116 and extends beyond the exterior edge 1120 of the guide foot 1106.

The drill guide 1100 also may include spindle lock assemblies, a rod wiper, an internal bushing, a retaining clip, and a chip breaker that function substantially the same as described above with respect to drill guide 200.

FIG. 13 shows an exemplary chucked hand-held drill 1300. The chucked hand-held drill 1300 includes features similar to the hand-held drill 100 shown in FIG. 1 . However, the chucked hand-held drill 1300 differs from the hand-held drill 100 in that the chucked hand-held drill 1300 includes a chuck 1302 instead of a quick release mechanism. The chuck 1302 is configured to retain a drill bit 1304 in the chucked hand-held drill 1300. While the chucked hand-held drill 1300 includes other features similar to the hand-held drill 100 shown in FIG. 1 , this is not required. In other embodiments, the chucked hand-held drill may include other features that differ from the features of the hand-held drill 100 shown in FIG. 1 .

The chuck 1302 is coupled to a collar 1306 that is a non-moving portion of the chucked hand-held drill 1300. The chuck 1302 is rotatable relative to the collar 1306. In other words, the chuck 1302 is part of a rotating portion of the chucked hand-held drill 1300. The chuck 1302 includes a sleeve 1308, a body 1310, and a plurality of jaws 1312. The sleeve 1308 includes a plurality of teeth 1314 formed around a perimeter of the sleeve 1308. The body 1310 includes a plurality of keyholes 1316 spaced apart around the perimeter of the body 1310. Each keyhole 1316 is configured to receive a chuck key 1318. When the chuck key 1318 is inserted into a keyhole 1316, teeth 1320 on the chuck key 1318 mate with the teeth 1314 on the sleeve 1308, such that rotation of the chuck key 1318 causes rotation of the body 1310 relative to the sleeve 1308. Rotation of the body 1310 relative to the sleeve 1308 causes the plurality of jaws 1312 to move in or out along an internal tapered surface (not shown) within the body 1310 and thus increase or decrease the space between the jaws 1312. The direction of rotation of the chuck key 1318 dictates whether the jaws 1312 extend or retract. The jaws 1312 may extend to clamp the drill bit 1304 to the chucked hand-held drill 1300. Further, the jaws 1312 may retract to release the drill bit 1304 from the chucked hand-held drill 1300. The chuck key 1318 provides suitably high torque to rotate the body 1310 relative to the sleeve 1308 to adjust the chuck 1302. The chucked hand-held drill 1300 is non limiting, and the drill guides disclosed herein may be adapted to work with virtually any type of chucked or non-chucked hand-held drill.

FIGS. 14 and 15 show an exemplary drill guide 1400 configured to couple to the chucked hand-held drill 1300 of FIG. 13 . The drill guide 1400 includes a mount 1402, a coupler 1404, a telescoping guard 1406, and a guide foot 1408. The coupler 1404 extends from the mount 1402. The telescoping guard 1406 extends from the coupler 1404. The guide foot 1408 is coupled to the telescoping guard 1406 opposite the mount 1402. The mount 1402 is configured to couple to a non-rotating portion of the hand-held drill 1300 and coaxially align the coupler 1404, the telescoping guard 1406, and the guide foot 1408 with the drill bit 1304. In the illustrated embodiment, the mount 1402 is configured to clamp to the non-rotating collar 1306 shown in FIG. 13 . In other embodiments, the mount may be configured to couple to a different non-rotating component of the chucked hand-held drill and/or couple in a non-clamping fashion.

The coupler 1404 forms a chuck access window 1410 that is aligned with the chuck 1302 when the mount 1402 is coupled to the non-rotating portion (e.g., the collar 1306 shown in FIG. 13 ) of the chucked hand-held drill 1300, thereby allowing the chuck key 1318 to interface with the chuck 1302. In this way, the chuck key 1318 can be used to adjust the chuck 1302 to remove the drill bit 1304 from the chucked hand-held drill 1300 while the drill guide 1400 is coupled to the chucked hand-held drill 1300. Such a feature allows for different drill bits to be quickly swapped out of the chucked hand-held drill 1300 without removing the drill guide 1400.

The coupler 1404 may be configured to form a chuck access window having any suitable size and/or dimensions to allow a chuck key to interface with a chuck. In some embodiments, the chuck access window may span a significant portion of the surface of the coupler in order to reduce an amount of material that forms the coupler and correspondingly reduces and overall weight of the coupler. In some embodiments, the coupler may form a plurality of chuck access windows spaced apart around a perimeter of the coupler to allow different points of access to the chuck. The coupler may form any suitable number of chuck access windows.

The telescoping guard 1406 is configured to telescope into a retracted position from an extended position. When the telescoping guard 1406 is in the extended position (shown in FIG. 14 ), the drill guide 1400 fully enshrouds the drill bit 1304. In other words, the telescoping guard 1406 forms a physical barrier between the drill bit 1304 and a human operator's hands so that the human operator's hands are protected from the drill bit 1304. The telescoping guard 1406 is configured to telescope from the extended position (shown in FIG. 14 ) to the retracted position (shown in FIG. 15 ). For example, during use, the telescoping guard 1406 telescopes from the extended position into the retracted position, thus allowing the drill bit 1304 to penetrate into a material being drilled (not shown). The telescoping guard 1406 is fully retracted when the telescoping guard 1406 abuts the coupler 1404.

The drill bit 1304 passes through both the telescoping guard 1406 and then the guide foot 1408, as the telescoping guard 1406 telescopes into the retracted position from the extended position. In this way, the drill bit 1304 continues to be enshrouded collectively by the drill guide 1400 and the material being drilled as the drill bit 1304 drills into the material. Accordingly, the drill bit 1304 is not exposed to an operator's hand during manual drilling operations.

Note that even when the telescoping guard 1406 telescopes into the retracted position, the chuck access window 1410 remains aligned with the chuck 1302 to allow for the chuck key 1318 to interface with the chuck 1302.

The guide foot 1408 is configured to align the drill bit 1304 normal to a surface of a material to be drilled by the chucked hand-held drill 1300. Such surface-normal alignment is achieved by the drill bit 1304 being coaxially aligned with the guide foot 1408 via the coupling of the mount 1402 to the non-rotating portion of the chucked hand-held drill 1300. In other embodiments, the guide foot may be angled to align the drill bit at a desired, non-normal angle (e.g., 45 degrees).

FIG. 16 shows an exploded view of the drill guide 1400. The mount 1402 includes a clamp bolt 1600 configured to screw into a threaded aperture 1602 to selectively reduce an interior diameter of the mount 1402, to clamp to a non-rotating portion of a chucked hand-held drill, such as the non-rotating collar 1306 of the chucked hand-held drill 1300 shown in FIG. 13 . The mount 1402 includes a plurality of radial pins 1604 that extend radially inward beyond an interior surface of the mount 1402. The plurality of radial pins 1604 are configured to interface with a twist-to-lock mechanism 1608 of the coupler 1404 to removably affix the coupler 1404 to the mount 1402.

The coupler 1404 includes a drill guide retention feature 1606 in the form of the twist-to-lock mechanism 1608 that is configured to removably affix the coupler 1404 to the mount 1402. In particular, the mount 1402 includes a receiving portion 1610 and the coupler 1404 includes an inserting portion 1612. The inserting portion 1612 includes a plurality of L-shaped slots 1614 formed in the side of the inserting portion 1612. The inserting portion 1612 may be inserted into the receiving portion 1610 until the radial pins 1604 are stopped at a heel of each of the L-shaped slots 1614. The coupler 1404 may be rotated clockwise to move the radial pins 1604 to a toe of each of the L-shaped slots 1614 to affix coupler 1404 to the mount 1402.

A retention spring 1616 may be positioned intermediate the mount 1402 and the coupler 1404. The retention spring 1616 is configured to apply an axial spring force to bias the coupler 1404 such that the retention pins 1604 are retained in the toe portion of the L-shaped slots 1614. In the illustrated embodiment, the retention spring 1616 comprises a wavy spring washer. The wavy spring washer provides suitable spring force to bias the coupler while having a thin form factor. In other embodiments, other types of springs may be used to bias the coupler.

The twist-to-lock mechanism 1608 may take any suitable form. The coupler may include any suitable number of retention slots and the mount may include the corresponding number of radial pins. The retention slots formed in the coupler may have any suitable shape. In some embodiments, the coupler may form a receiving portion and the mount may form an inserting portion having radial pins that extend radially outward from the mount to interface with the retention slots of the coupler. In some embodiments, the radial pins may be outwardly biased and the retention slots each may include a depressable catch. In such a configuration the catch may be depressed to release the pin from the retention slot in order for the coupler to be twisted relative to the mount.

In other embodiments, the retention feature 1606 may take a form different than the illustrated twist to lock mechanism. In some embodiments, the coupler and the mount may be threaded such that the coupler may be screwed into the mount to affix the coupler to the mount. In some embodiments, the mount and/or the coupler may include one or more magnets that are configured to affix the coupler to the mount. In some embodiments, the coupler may include a fastener or a clasp that is configured to affix the coupler to the mount. The retention feature may take any suitable form.

The telescoping guard 1406 comprises an interior guard 1618 and an exterior guard 1620. The interior guard 1618 extends from the coupler 1404. A rod wiper 1622, an internal bushing 1624, and an internal retaining ring 1626 are configured to be coupled inside the exterior guard 1620. The rod wiper 1622 is configured to keep the telescoping guard 1406 clean and free from foreign matter by preventing contaminants from reaching an interior portion of the telescoping guard 1406. The internal bushing 1624 is configured to reduce friction between the interior guard 1618 and the exterior guard 1620 during telescoping operation of the telescoping guard 1406. The internal retaining ring 1626 is configured to retain the rod wiper 1622 and the internal bushing 1624 within the exterior guard 1620. Moreover, the retainer ring 1626 is configured to retain the interior guard 1618 within the exterior guard 1620, such that the guards cannot telescope apart when the telescoping guard 1406 is in the extended position.

A retention flange 1628 is installed within the exterior guard 1620, such that the retaining ring 1626 abuts against the retention flange 1628 when the telescoping guard 1406 is fully extended. In this way, the retention flange 1628 retains the exterior guard 1620 on the interior guard 1618 when the telescoping guard 1406 is fully extended.

A coil spring 1630 is positioned intermediate the retention flange 1628 and the guide foot 1408. The coil spring 1630 is configured to bias the telescoping guard 1406 toward the extended position, such that the drill bit may be enshrouded absent a retraction force that overcomes the bias of the coil spring 1630.

The guide foot 1408 is configured to couple to the telescoping guard 1406 opposite the mount 1402. In the illustrated embodiment, the guide foot 1408 includes threads 1632 that are matched to complementary threads (not shown) that are positioned within the exterior guard 1620, such that the guide foot 1408 can be screwed onto the exterior guard 1620. The guide foot may couple to the exterior guard in any suitable manner.

The guide foot 1408 includes a bushing 1634 configured to couple to the guide foot 1408. In the illustrated embodiment, the bushing 1634 includes threads 1636 that are matched to complementary threads (not shown) that are positioned within the guide foot 1408, such that the bushing 1634 can be screwed into the guide foot 1408. The bushing may couple to the guide foot in any suitable manner.

The bushing 1634 has an interior diameter matched to a diameter of the drill bit (i.e., the bushing 1634 is large enough to allow the drill bit to freely rotate, but small enough to severely limit or prevent lateral deflection of the drill bit). The bushing 1634 is configured such that the drill bit passes through the bushing 1634 as the telescoping guard 1406 telescopes into the retracted position from the extended position. The matched interior diameter of the bushing 1634 provides lateral stability to help maintain alignment of the drill bit relative to the surface of the material being drilled during manual drilling operations. The bushing 1634 includes a chip breaker 1638 that is configured to break drilling debris into pieces suitably small enough to be expelled in a controlled manner.

In some embodiments, the bushing 1634 may be one of a plurality of different bushings that are each configured to be interchangeably coupled to the guide foot 1408. In some examples, different bushings may have different interior diameters to accommodate differently-sized drill bits. In some examples, different bushing may have different types of chip breakers that are configured to break up different types of material. Any suitable type of bushing may be interchangeably coupled into the guide foot.

FIGS. 17-19 show the twist-to-lock mechanism 1608 of the drill guide 1400 demonstrating the manner in which the coupler 1404 affixes to the mount 1402. Note that non-relevant components of the drill guide 1400 and the chucked hand-held drill 1300 are omitted for ease of illustration in FIGS. 17-19 .

In FIG. 17 , the drill bit 1304 is clamped into the chuck 1302 of the chucked hand-held drill 1300. The mount 1402 is coupled to a non-moving portion of the chucked hand-held drill 1300 (e.g., the collar 1306). The coupler 1404 is aligned with a longitudinal axis 1700 of the drill bit 1304, such that the drill bit passes through the coupler 1404 and the twist-to-lock mechanism 1608 is aligned to receive the radial pin 1604. Note that in this state that the retention spring 1616 is not compressed between the coupler 1404 and the mount 1402.

In FIG. 18 , the coupler 1404 is translated leftward relative to FIG. 17 such that the inserting portion 16 of the coupler 1404 is inserted into the receiving portion 1610 of the mount 1402 until the radial pin 1604 is stopped at the heel of the L-shaped slot 1614. In this state, the coupler 1404 compresses the retention spring 1616 against the mount 1402 such that the retention spring 1616 applies an axial spring force along the longitudinal axis 1700 to bias the coupler 1404.

In FIG. 19 , the coupler 1404 is rotated clockwise relative to the mount 1402 to move the radial pin 1604 into the toe of the L-shaped slot 1614. The retention spring 1616 biases the coupler 1404 such that the radial pin 1604 is retained in the toe of the L-shaped slot 1614 to affix the coupler 1404 to the mount 1402. The coupler 1404 may be rotated counterclockwise to remove the coupler from the mount 1402.

The twist-to-lock mechanism 1608 allows for the drill guide 1400 to be quickly and easily removed from the chucked hand-held drill without having to unclamp the mount 1402. For example, the drill guide 1400 may be removed from the chucked hand-held drill to swap out a drill bit for another drill bit. In some embodiments, a coupler of a drill guide may include a twist-to-lock mechanism without having a chuck access window. For example, such a drill guide may be used on a non-chucked drill, such as the drill 100 shown in FIG. 1 .

In some embodiments, a drill guide may include a chuck access window without including a twist-to-lock mechanism or another form of drill guide retention feature that is incorporated into a coupler. FIG. 20 shows aspects of an exemplary drill guide 2000 including a mount 2002 that forms a chuck access window 2004. The mount 2002 is configured to couple to a non-rotating portion of the chucked hand-held drill 1300. In the illustrated embodiment, the coupler is integral with the mount, such that the mount 2002 forms the chuck access window 2004 that is aligned with the chuck 1302 when the mount 1402 is coupled to the non-rotating portion of the chucked hand-held drill 1300, thereby allowing a chuck key to interface with the chuck 1302. Note that other components of the drill guide 2000 and the chucked hand-held drill 1300 are omitted for ease of illustration in FIG. 20 .

FIGS. 21-22 show the drill guide 1400 in the extended position and the retracted position. In FIG. 21 , the drill guide 1400 is shown coupled to the hand-held drill 1300, with the telescoping guard 1406 in the extended position. When the drill guide 1400 is coupled to the hand-held drill 1300, the mount 1402, the coupler 1404, the telescoping guard 1406, and the guide foot 1408 including the bushing 1634 are coaxially aligned with the drill bit 1304 along a longitudinal axis 2100. When the telescoping guard 1406 is in the extended position, the drill guide 1400 fully enshrouds the drill bit 1304. Additionally, when the drill guide 1400 is coupled to the hand-held drill 1300 and the telescoping guard 1406 is in the extended position, the chuck access window 1410 aligns with the chuck 1302 thereby allowing the chuck key 1318 to interface with the chuck 1302.

In FIG. 22 , the drill guide 1400 is again shown coupled to the hand-held drill 1300, but with the telescoping guard 1406 in the retracted position. The telescoping guard 1406 telescopes with rear-action along the longitudinal axis 2100 from the extended position toward the retracted position, as shown by the horizontal directional arrows 2200A, 2200B in FIG. 22 . When the telescoping guard 1406 telescopes from the extended position toward the retracted position, the drill bit 1304 passes through the guide foot 1408 including the bushing 1634, such that the drill bit 1304 extends beyond an exterior edge of the guide foot 1408. Additionally, when the drill guide 1400 is coupled to the hand-held drill 1300 and the telescoping guard 1406 is in the retracted position, the chuck access window 1410 aligns with the chuck 1302 thereby allowing the chuck key 1318 to interface with the chuck 1302. In other words, the chuck access window remains aligned with the chuck 1302 regardless of the extended/retracted state of the telescoping guard.

In some embodiments, a vacuum shroud can be removably fastened to a drill guide that is coupled to a hand-held drill, so that the vacuum shroud can collect debris from a drilling operation performed by a drill bit of the hand-held drill. FIGS. 23-24 show an example embodiment of a vacuum shroud 2300. The vacuum shroud 2300 is connectable to a vacuum hose that creates a vacuum that draws debris through a vacuum cavity at least partially formed by the vacuum shroud 2300 into the vacuum hose for collection. The vacuum shroud 2300 includes an outer wall 2302 forming an elongate vacuum cavity 2304 between an inlet 2306 and an outlet 2308. A vacuum hose connector 2310 is positioned at the outlet 2308 distal from the inlet 2306. A forward collar 2312 extends from the outer wall 2302 proximate to the inlet 2306 of the elongate vacuum cavity 2304. The vacuum shroud 2300 further includes a rearward collar 2314 extending from the outer wall 2302 between the forward collar 2312 and the vacuum hose connector 2310.

In the illustrated embodiment, the forward collar 2312 is rounded to fit a contour of a cylindrical shape of a guide foot 2608 of a drill guide 2600 (shown in FIGS. 26-27 ), such that the forward collar 2312 is clampable to the guide foot 2608. Also, the rearward collar 2314 is rounded to fit a contour of a telescoping guard 2606 of the drill guide 2600, such that the forward collar 2312 is clampable to the telescoping guard 2606. The forward and rearward collars 2312, 2314 are elastically deformable and allow for the vacuum shroud 2300 to fasten to the drill guide 2600 with suitable friction (e.g., via a press fit) for the vacuum shroud 2300 to remain fastened to the drill guide 2600 during operation of a hand-held drill 2602. In other embodiments, the forward and rearward collars 2312, 2314 can be configured to clamp to other components of the drill guide 2600. In still other embodiments, the vacuum shroud 2300 can be removably fastened to the drill guide 2600 in a different manner, such as via other types of fasteners (e.g., straps, screws, magnets).

As shown in FIG. 24 , the vacuum shroud 2300 includes an index pin 2316 that is insertable into a corresponding index hole 2618 of the drill guide 2600 (shown in FIGS. 26-27 ) when the vacuum shroud 2300 is fastened to the drill guide 2600. The index pin 2316 is insertable into the index hole 2618 when the vacuum shroud 2300 is fastened to the drill guide 2600 to align the inlet 2306 of the elongate vacuum cavity 2304 with a debris clearing recess 2620 of the drill guide 2600 (shown in FIGS. 26-27 ). Such alignment allows for debris from a drilling operation performed by a drill bit 2612 of the hand-held drill 2602 to be collected into the elongate vacuum cavity 2304 and drawn into the vacuum hose 2704 (shown in FIG. 27 ). In some embodiments, the configuration may be reversed such that the guide foot includes an index pin and the vacuum shroud includes an index hole, or another indexing mechanism may be used.

Returning to FIG. 23 , the vacuum shroud 2300 includes an outlet shaft 2318 at the outlet 2308 of the elongate vacuum cavity 2304. The vacuum hose connector 2310 is captively retained on the outlet shaft 2318. As used herein, the term “captively retained” means that the vacuum hose connector 2310 can move relative to the outlet shaft 2318, but the vacuum hose connector 2310 cannot be removed from the outlet shaft 2318. In particular, the vacuum hose connector 2310 is rotatable relative to the outlet shaft 2318 to allow for the vacuum hose connector 2310 to be twisted without the outer wall 2302 needing to be twisted.

The vacuum hose connector 2310 includes a plurality of retention ridges 2320 disposed on an exterior surface 2322 of the vacuum hose connector 2310. The vacuum hose 2704 (shown in FIG. 27 ) is retained on the vacuum hose connector 2310 via friction between the plurality of retention ridges 2320 and an interior surface of the vacuum hose 2704. For example, the vacuum hose 2704 can be press fit onto the vacuum hose connector 2310 to connect the vacuum hose 2704 to the vacuum shroud 2300. The vacuum hose connector 2310 may include any suitable number of retention ridges to retain the vacuum hose 2704 on the vacuum hose connector 2310. In other embodiments, the retention ridges 2320 may be threaded, such that the vacuum hose 2704 screws onto the vacuum hose connector 2310. In still other embodiments, the vacuum hose 2704 may be configured to be inserted into the vacuum hose connector 2310 to connect the vacuum hose 2704 to the vacuum shroud 2300.

FIG. 25 shows a partial cross-section view of the vacuum shroud 2300. In some embodiments, the vacuum shroud 2300 is manufactured using an additive manufacturing process that allows for the vacuum hose connector 2310 to be captively retained on the outlet shaft 2318. In such embodiments, the vacuum shroud 2300 is an additively manufactured vacuum shroud that is produced/printed as a single part. In some examples, the additively manufactured vacuum shroud 2300′ is produced using a powder-based additive manufacturing method. The additively manufactured vacuum shroud 2300′ includes the additively manufactured outer wall 2302′. The additively manufactured outer wall 2302′ forms the elongate vacuum cavity 2304 between the inlet 2306 and the outlet 2308. The additively manufactured vacuum shroud 2300′ further includes the additively manufactured outlet shaft 2318′ extending from the outlet 2308 of the elongate vacuum cavity 2304. The additively manufactured vacuum hose connector 2310′ encircles the additively manufactured outlet shaft 2318′.

The additively manufactured outlet shaft 2318′ includes a retention ring 2500 disposed on an exterior surface 2502 of the additively manufactured outlet shaft 2318′. Further, the additively manufactured vacuum hose connector 2310′ includes a channel 2504 disposed on an interior surface 2506 of the additively manufactured vacuum hose connector 2310′. The channel 2504 envelopes the retention ring 2500 to captively retain the additively manufactured vacuum hose connector 2310′ on the additively manufactured outlet shaft 2318′.

A manufacturing spacer 2508′ is intermediate the additively manufactured outlet shaft 2318′ and the additively manufactured vacuum hose connector 2310′. In this embodiment, the additively manufactured outer wall 2302′, the additively manufactured outlet shaft 2318′, and the additively manufactured vacuum hose connector 2310′ are solid components, and the manufacturing spacer 2508′ is a powder-based component. The manufacturing spacer 2508′ is removable to allow the additively manufactured vacuum hose connector 2310′ to rotate relative to the additively manufactured outlet shaft 2318′ . For example, the additively manufactured vacuum shroud 2300′ can be agitated after production to allow the powder that makes up the manufacturing spacer 2508′ to be removed. Further, after the powder that makes up the manufacturing spacer 2508′ is removed, the retention ring 2500 remains captive in the channel 2504 to captively retain the additively manufactured vacuum hose connector 2310′ on the additively manufactured outlet shaft 2318′.

An additively manufactured forward collar 2324′ extends from the additively manufactured outer wall 2302′ proximate to the inlet 2306. An additively manufactured rearward collar 2326′ extends from the additively manufactured outer wall 2302′ between the additively manufactured forward collar 2324′ and the additively manufactured vacuum hose connector 2310′.

In other embodiments, the additively manufactured vacuum shroud can be produced from a different additive manufacturing process other than a powder-based manufacturing process. In still other embodiments, the vacuum shroud can be produced from a different type of manufacturing process that is not an additive-manufacturing process. In some embodiments, the vacuum shroud may include a plurality of separate components that are coupled together to form the vacuum shroud.

FIG. 26 shows an exemplary drill guide 2600 coupled to a hand-held drill 2602. The drill guide 2600 includes a mount 2604, a telescoping guard 2606, and a guide foot 2608. The mount 2604 is configured to couple to a non-rotating portion 2610 of the hand-held drill 2602. The telescoping guard 2606 extends from the mount 2604. The telescoping guard 2606 is shown in an extended position. The telescoping guard 2606 is configured to telescope into a retracted position from the extended position. The guide foot 268 is coupled to the telescoping guard 2606 opposite the mount 2604 such that the drill guide enshrouds a drill bit 2612 of the hand-held drill 2602 when the telescoping guard 2606 is in the extended position. The drill bit 2612 passes through an opening in the guide foot 2608 as the telescoping guard 2606 telescopes into the retracted position from the extended position.

The drill guide 2600 includes various features that facilitate the vacuum shroud 2300 to fasten to the drill guide 2600. A rearward recessed channel 2614 is formed in the telescoping guard 2606. The rearward recessed channel 2614 is configured to receive the rearward collar 2314 of the vacuum shroud 2300 when the vacuum shroud 2300 is fastened to the drill guide 2600. A forward recessed channel 2616 is formed in the guide foot 2608. The forward recessed channel 2616 is configured to receive the forward collar 2312 of the vacuum shroud 2300 when the vacuum shroud 2300 is fastened to the drill guide 2600.

Further, the guide foot 2608 includes the index hole 2618 that corresponds to the index pin 2316 of the vacuum shroud 2300. The index pin 2316 is insertable into the index hole 2618 when the vacuum shroud 2300 is fastened to the drill guide 2600 to align the inlet 2306 of the elongate vacuum cavity 2304 of the vacuum shroud 2300 with the debris clearing recess 2620 formed in the forward edge 2622 of the guide foot 2608 (shown in FIG. 27 ).

The debris clearing recess 2620 is sized to allow debris produced during a drilling operation performed by the drill bit 2612 to be cleared from the front of the guide foot 2608 into the elongate vacuum cavity 2304 of the vacuum shroud 2300 before the debris can enter an interior cavity of the telescoping guard 2606. In this way, debris does not interfere with operation (e.g., rotation) of the drill bit 2612.

Further, a plurality of airflow recesses 2624 are formed in the forward edge 2622 of the guide foot 2608. The plurality of airflow recesses 2624 are each smaller than the debris clearing recess 2620. The guide foot 2608 may include any suitable number of airflow recesses.

The arrangement of the debris clearing recess 2620 and the plurality of airflow recesses 2624 around the forward edge 2622 of the guide foot 2608 allow for the guide foot 2608 to have three points of contact against a drilling surface during a drilling operation. Such an arrangement provides stability to inhibit slippage of the drill bit during a drilling operation.

The plurality of airflow recesses 2624 allow for air to flow into the guide foot 2608 when the forward edge 2622 of the guide foot is pressed against a drilling surface during a drilling operation. Such airflow helps create a vacuum in the elongate vacuum cavity 2304 of the vacuum shroud 2300 that causes debris to flow through the debris clearing recess 2620 into the elongate vacuum cavity 2304.

FIG. 27 shows an assembly 2700 including the vacuum shroud 2300 fastened to the drill guide 2600. The assembly 2700 can be coupled to the hand-held drill 2602. The forward collar 2312 of the vacuum shroud 2300 is clamped in the forward recessed channel 2616 of the guide foot 2608 such that the index pin 2316 is inserted in the index hole 2618, such that the inlet 2306 of the elongate vacuum cavity 2304 is proximate to the forward edge 2622 of the guide foot 2608 and aligned with the debris clearing recess 2620. The rearward collar 2314 of the vacuum shroud 2300 is clamped to the rearward recessed channel 2614 of the telescoping guard 2606.

In the illustrated embodiment, a forward edge 2702 of the vacuum shroud 2300 is recessed relative to the forward edge 2622 of the guide foot 2608. This recess provides another source of airflow that helps create the vacuum in the elongate vacuum cavity 2304 of the vacuum shroud 2300. In other embodiments, the forward edge of the vacuum shroud may be flush with the forward edge of the guide foot.

When the vacuum shroud 2300 is fastened to the drill guide 2600, the vacuum hose connector 2310 at the outlet 2308 of the elongate vacuum cavity 2304 is distal from the guide foot 2608. The vacuum hose connector 2310 is connected to a vacuum hose 2704. Suction is provided through the vacuum hose 2704 to draw debris from the front of the guide foot 2608, through the debris clearing recess 2620, into the elongate vacuum cavity 2304, and further into the vacuum hose 2704. In some examples, the suction in the vacuum hose 2704 is provided by an air compressor that also provides power to operate the hand-held drill 2602. In other examples, the suction in the vacuum hose 2704 may be provided by a different source. In some examples, the vacuum hose 2704 may be coupled to a collection bag (not shown) where debris is collected for disposal.

The position of the vacuum hose 2704 distal from the forward edge 2622 of the guide foot 2608 allows for the assembly 2700 to have a narrow profile. The narrow profile allows for the hand-held drill 2602 to be used for drilling operations in tight-fitting spaces. Further, the contour of the outer wall 2302/elongate vacuum cavity 2304 allow for the vacuum shroud 2300 to be comfortably held with two hands by an operator during operation of the hand-held drill 2602. Such two-handed operation of the hand-held drill 2602 provides stable control of the hand-held drill 2602 that inhibits slippage of the drill bit 2612 and reduces fatigue of the operator relative to other ways of operating the hand-held drill 2602.

Further, the vacuum shroud 2300, the guide foot 2608, and the telescoping guard 2606 are collectively axially rotatable relative to the mount 2604 when the vacuum shroud 2300 is fastened to the drill guide 2600. Such axial rotation allows for the vacuum shroud 2300 and the vacuum hose 2704 to be easily moved to a position that does not interfere with operation of the hand-held drill 2602 in a tight-fitting space. Moreover, such axial rotation allows for the assembly 2700 to be easily adjusted for use by operators having different dominant hands or that prefer different grips while operating the hand-held drill 2602.

In the illustrated embodiment, the elongate vacuum cavity 2304 is cooperatively formed by at least an interior surface of the outer wall 2302 of the vacuum shroud 2300 and the exterior surfaces of the telescoping guard 2606 and the guide foot 2608. Such an arrangement may reduce an amount of materials and a cost to manufacture the vacuum shroud 2300 relative to a vacuum shroud that includes walls that enclose the elongate vacuum cavity without cooperation from the exterior surfaces of the telescoping guard and the guide foot. In such arrangements, elastic gaskets or other seals may be incorporated on the vacuum shroud and/or the drill guide to reduce unwanted airflow and promote a stronger vacuum.

In other embodiments, a vacuum shroud may include walls that enclose an elongate vacuum cavity without cooperation of exterior surfaces of a drill guide. FIGS. 28-29 show another embodiment of a vacuum shroud 2800 including inner and outer walls that enclose an elongate vacuum cavity. FIG. 28 shows a cross-section view of the vacuum shroud 2800. FIG. 29 shows a bottom view of the vacuum shroud 2800.

The vacuum shroud 2800 includes an outer wall 2802 and inner wall 2804 connected to the outer wall 2802. At least the inner wall 2804 and the outer wall 2802 cooperatively form an elongate vacuum cavity 2806 between an inlet 2808 and an outlet 2810 distal from the inlet 2808. A vacuum hose connector 2812 is positioned at the outlet 2810. The vacuum shroud 2800 includes a forward collar 2814 extending from the outer wall 2802 and clampable to a guide foot of a drill guide, such as the guide foot 2608 of the drill guide 2600 shown in FIG. 26 . The vacuum shroud 2800 further includes a rearward collar 2816 extending from the outer wall 2802 and clampable to a telescoping guard, such as the telescoping guard 2606 of the drill guide 2600 shown in FIG. 26 . Features of the vacuum shroud that have been discussed previously are discussed no further.

The vacuum shroud 2800 having inner and outer walls that collectively form a vacuum cavity may be suitable for use with drill guides having exterior surface features that do not allow for the exterior surface to cooperatively form a vacuum in the elongate vacuum cavity. For example, some drill guides may include holes along the shaft that allow for airflow for cooling. Such drill guides would not have a suitable surface for cooperatively forming walls of a vacuum cavity in the vacuum shroud.

Various components of the herein described drill guides and vacuum shrouds may be optional. For example, in some embodiments, the spindle lock assemblies, the bushing, the chip breaker, drill guide retention feature, and/or chuck access window may be omitted from the drill guide. Various components of the drill guide may be differently configured in different embodiments. For example, different embodiments of the drill guide may have different mounts (e.g., using fasteners, latches, compression fit, magnets), different shaped telescoping guards (e.g., concentric, eccentric, cylindrical, rectangular, pentagonal, hexagonal, octagonal, or other polygonal), different numbers of telescoping segments (e.g., 2, 3, 4 or more), rear-action or front-action telescoping segments, different guide feet (e.g., normal to surface, angled relative to surface, without a bushing, with interchangeable bushings), and/or different drill guide retention features (e.g., magnets, threads, quick disconnects, fasteners). In some embodiments, the forward collar, the rearward collar, the index pin, and/or the captively retained vacuum hose connector may be omitted from the vacuum shroud. A telescoping and enshrouding drill guide and/or vacuum shroud may include any suitable combination of these different components, and/or other components, without departing from the spirit of this disclosure.

The present disclosure includes all novel and non-obvious combinations and subcombinations of the various features and techniques disclosed herein. The various features and techniques disclosed herein are not necessarily required of all examples of the present disclosure. Furthermore, the various features and techniques disclosed herein may define patentable subject matter apart from the disclosed examples and may find utility in other implementations not expressly disclosed herein. 

1. An assembly for a hand-held drill, the assembly comprising: a drill guide including: a mount configured to couple to a non-rotating portion of the hand-held drill; a telescoping guard extending from the mount and configured to telescope into a retracted position from an extended position; and a guide foot coupled to the telescoping guard opposite the mount such that the drill guide enshrouds a drill bit of the hand-held drill when the telescoping guard is in the extended position, wherein the drill bit passes through an opening in the guide foot as the telescoping guard telescopes into the retracted position from the extended position; and a vacuum shroud removably fastenable to the drill guide, the vacuum shroud including: an outer wall forming an elongate vacuum cavity between an inlet proximate to the guide foot and an outlet distal from the guide foot; and a vacuum hose connector at the outlet distal from the guide foot.
 2. The assembly of claim 1, wherein the vacuum shroud includes a forward collar extending from the outer wall and clampable to the guide foot.
 3. The assembly of claim 1, wherein the vacuum shroud includes a rearward collar extending from the outer wall and clampable to the telescoping guard.
 4. The assembly of claim 1, wherein the vacuum shroud, the guide foot, and the telescoping guard are collectively axially rotatable relative to the mount when the vacuum shroud is fastened to the drill guide.
 5. The assembly of claim 1, wherein a debris clearing recess is formed in a forward edge of the guide foot, and wherein the inlet of the elongate vacuum cavity is aligned with the debris clearing recess.
 6. The assembly of claim 5, wherein one or more airflow recesses are formed in the forward edge of the guide foot, wherein the one or more airflow recesses are smaller than the debris clearing recess.
 7. The assembly of claim 1, wherein a forward edge of the vacuum shroud is recessed relative to a forward edge of the guide foot.
 8. The assembly of claim 1, wherein the vacuum shroud includes an index pin, wherein the guide foot includes a corresponding index hole, and wherein the index pin is insertable into the index hole when the vacuum shroud is fastened to the drill guide to align the inlet of the elongate vacuum cavity with the debris clearing recess.
 9. The assembly of claim 1, wherein the vacuum shroud includes an outlet shaft at the outlet of the elongate vacuum cavity, wherein the vacuum hose connector is captively retained on the outlet shaft, and wherein the vacuum hose connector is rotatable relative to the outlet shaft.
 10. The assembly of claim 9, wherein the outlet shaft includes a retention ring disposed on an exterior surface of the outlet shaft, wherein the vacuum hose connector includes a channel disposed on an interior surface of the vacuum hose connector, and wherein the channel envelopes the retention ring to captively retain the vacuum hose connector on the outlet shaft.
 11. The assembly of claim 1, wherein one or more retention ridges are disposed on an exterior surface of the vacuum hose connector, and wherein a vacuum hose is retained on the vacuum hose connect via friction between the one or more retention ridges and an interior surface of the vacuum hose.
 12. The assembly of claim 1, wherein the vacuum shroud includes an additively manufactured outer wall, an additively manufactured outlet shaft extending from the additively manufactured outer wall at the outlet of the elongate vacuum cavity, an additively manufactured vacuum hose connector encircling the outlet shaft, and a manufacturing spacer intermediate the additively manufactured outlet shaft and the additively manufactured vacuum hose connector, wherein the additively manufactured outer wall, the additively manufactured outlet shaft, and the additively manufactured vacuum hose connector are solid components, and wherein the manufacturing spacer is a powder-based component that is removable to allow the additively manufactured vacuum hose connector to be rotatably retained on the additively manufactured outlet shaft.
 13. The assembly of claim 1, wherein the elongate vacuum cavity is cooperatively formed by at least the outer wall of the vacuum shroud, an exterior surface of the guide foot, and an exterior surface of the telescoping guard.
 14. The assembly of claim 1, wherein the vacuum shroud includes an inner wall connected to the outer wall, and wherein at least the inner wall and the outer wall cooperatively form the elongate vacuum cavity.
 15. A vacuum shroud for collecting debris from a drilling operation performed by a drill bit of a hand-held drill equipped with a drill guide, the vacuum shroud including: an outer wall forming an elongate vacuum cavity between an inlet proximate to a drill bit extending through the drill guide and an outlet distal from the drill bit; a vacuum hose connector at the outlet distal from the drill bit; a forward collar extending from the outer wall and clampable to the drill guide between the drill bit and the vacuum hose connector; a rearward collar extending from the outer wall and clampable to the drill guide between the forward collar and the vacuum hose connector.
 16. The vacuum shroud of claim 15, wherein the vacuum shroud includes an index pin, wherein the drill guide includes a corresponding index hole, and wherein the index pin is insertable into the index hole when the vacuum shroud is removably fastened to the drill guide to align the inlet of the elongate vacuum cavity with a debris clearing recess of the drill guide.
 17. The vacuum shroud of claim 15, wherein the vacuum shroud includes an outlet shaft at the outlet of the elongate vacuum cavity, wherein the vacuum hose connector is captively retained on the outlet shaft, and wherein the vacuum hose connector is rotatable relative to the outlet shaft.
 18. The vacuum shroud of claim 17, wherein the outlet shaft includes a retention ring disposed on an exterior surface of the outlet shaft, wherein the vacuum hose connector includes a channel disposed on an interior surface of the vacuum hose connector, and wherein the channel envelopes the retention ring to captively retain the vacuum hose connector on the outlet shaft.
 19. The vacuum shroud of claim 15, wherein one or more retention ridges are disposed on an exterior surface of the vacuum hose connector, and wherein a vacuum hose is retained on the vacuum hose connect via friction between the one or more retention ridges and an interior surface of the vacuum hose.
 20. An additively manufactured vacuum shroud for collecting debris from a drilling operation performed by a drill bit of a hand-held drill equipped with a drill guide, the additively manufactured vacuum shroud including: an additively manufactured outer wall forming an elongate vacuum cavity between an inlet proximate to a drill bit extending through the drill guide and an outlet distal from the drill bit; an additively manufactured outlet shaft extending from the outlet of the elongate vacuum cavity; an additively manufactured vacuum hose connector encircling the additively manufactured outlet shaft; and a manufacturing spacer intermediate the additively manufactured outlet shaft and the additively manufactured vacuum hose connector, wherein the additively manufactured outer wall, the additively manufactured outlet shaft, and the additively manufactured vacuum hose connector are solid components, and wherein the manufacturing spacer is a powder-based component that is removable to allow the additively manufactured vacuum hose connector to be rotatably retained on the outlet shaft. 